Recurrent shoulder dislocation and management

RECURRENT
SHOULDER
DISLOCATION

INTRODUCTION
 One of the most unstable and frequently dislocated joint in the body.
 Greatest range of motion at expense of stability.
 50% of all dislocations
 In a study of 101 acute dislocations, recurrence developed in 90% of the
patients younger then 20 yrs old , in 60% of 20-40 yrs old and in only 10%
of patients older than 40yrs of age.

FACTORS INFLUENCING RECURRENT
DISLOCATION
1. AGE
2. RETURN TO CONTACT OR COLLISION SPORTS
3. HYPERLAXITY
4. PRESENCE OF SIGNIFICANT BONY DEFECT IN GLENOID OR HUMERAL
HEAD

ANATOMY
SHOULDER STABILIZERS
DYNAMIC STABILIZERSSTATIC STABILIZER

Static stabilizers
 Articular congruence
 Glenoid labrum
 Capsule and ligaments
 Negative intra articular pressure
 Adhesive cohesive forces

Dynamic stabilisers
 Rotator cuff muscles
 Biceps tendon
 Scapulo-thoracic motion

ARTICULAR CONGRUENCE
 Glenoid fossa
1. Pear shaped
2. 7 degrees retroversion
3. 5-10 degrees superior tilt
 Humerus
 Neck shaft angle 130- 140 degrees
 Retroversion 30 degrees

 Humeral head is 3 times larger than glenoid fossa and covers only 25-30%
of humeral head during any range of motion.
 Large humeral head articulating with small and shallow glenoid.

Glenoid Labrum
 Wedge shaped fibrous ring attached to the
glenoid articular surface through a
fibrocartilaginous transition zone.
 Contributes 20% to glenohumeral stability.
 It deepens glenoid cavity by 50%
 Serve as attachment site for glenohumeral
ligaments and biceps tendon.
 Increases surface contact area

CAPSULE AND GLENOHUMERAL
LIGAMENTS
 Capsule :
Glenohumeral joint capsule is loose and
redundant.
Attached medially to the glenoid fossa
Laterally to anatomical neck of humerus
Anterior capsule is thicker than posterior

GLENO HUMERAL LIGAMENTS
 It is the localised thickening of the capsule
 Named according to their attachments on the glenoid rim
 Actions-
limits of rotation
preventing excess gleno humeral translation
 Their function is dependent on the arm position and on the direction of the
applied force on the joint.

Recurrent shoulder dislocation and management

Superior Gleno-humeral ligament
 Origin- tubercle on glenoid, just posterior to long
head of biceps
 Insertion – upper end of lesser tubercle
 Present in > 90%
 Resists inferior subluxation and contributes to
stability in posterior and inferior directions.

Middle glenohumeral ligament
 Origin- superior glenoid labrum
 Insertion- blends with sub scapularis tendon
 Present in 60-80%
 Limits anterior instability, specially in 45 degrees.
Also limits external rotation

Inferior gleno humeral ligament
 Origin- anterior glenoid rim and labrum
 Insertion- inferior aspect of humeral articular
surface and anatomical neck
 Consists of three bands: anterior ,axillary and
posterior
 Primary restraint to anterior and posterior stresses
at 45-90 degree abduction.

 Inferior GH ligament for hammock type
model
 Most important ligamentous stabilizer

Negative intraarticular pressure
 The osmotic action of the synovium to remove fluid creates a negative
intra-articular pressure in the joint.
 This makes the pliable labrum centered by a non-compliant osseous
glenoid stick to the humeral head like a suction cup.
 This negative pressure is lost in capsular tear or excessive capsular
laxity.

Dynamic stabilizer – rotator cuff
 Fibrous sheath formed by the 4 flattened tendons.
 These tendons blend with each other and with the
capsule of shoulder joint before reaching their
point of insertion
 Usually consist of-
1. Subscapularis –internal rotation and adduction
of arm
2. Supraspinatus-abduction of the arm
3. Infraspinatus-external rotation of the arm
4. Teres minor-external rotation of arm

Rotator cuff
 Active contraction of the rotator cuff contributes to joint
stabilization by coordinated muscular activity and by secondary
tightening of the ligamentous constraints.
 This effect works in combination with the concavity-compression
mechanism, in which muscle contraction causes compression of
nearly congruent articular surfaces into one another.
 This coordinated compressive function of the rotator cuff muscles is required to
counteract the upward shearing force of the strong deltoid muscle during
abduction and/or flexion.

Biceps tendon
 Long head of biceps tendon- has variable
origin
 30-40% originating from the supraglenoid
tubercle
 45-60% directly from the labrum
 25-30% from both
 Long head of biceps helps limit anterior,
posterior and inferior translation of the
humeral head, specially in adduction.

Scapulo-thoracic motion
 Primarily achieved by the serratus anterior and trapezius muscles, which
provide overall rhythm of the shoulder motion.
 Maintains the glenoid as a stable platform underneath the humeral head
as the shoulder rotates into positions required for overhead motions such
as throwing.

CLASSIFICATION
 ACCORDING TO DIRECTION
1. UNIDIRECTIONAL
2. BIDIRECTIONAL
3. MULTIDIRECTIONAL
 DEGREE OF INSTABILITY
1. SUBLUXATION
2. DISLOCATION
 DURATION OF INSTABILITY
1. ACUTE
2. CHRONIC (>6 WEEKS)

 TYPE OF TRAUMA
1. MACROTRAUMA
2. MICROTRAUMA
3. SECONDARY TRAUMA
 AGE OF INTIAL DISLOCATION
1. <20 YEAR – 90% REOCCURENCE
2. 20-40 YEAR –
3. >40 YEAR – 10% REOCURRENCE

MATTSONS CLASSIFICATION
 TUBS
 Traumatic
 Unidirectional
 Bankart lesion
 Surgery is often necessary
 AMBRII
 Atraumatic
 Multidirectional
 Bilateral
 Rehabilitation is the primary mode of treatment
 Inferior capsular shift
 Internal closure often performed

SHOULDER DISLOCATION
TYPES ANTERIOR POSTERIOR INFERIOR
INCIDENCE 95-98%
(SUBCORACOID
MOST COMMON)
3-4% 1-2%
MECHANISM OF
INJURY
ABDUCTION ;
EXTERNAL
ROTATION
ADDUCTION ;
INTERNAL
ROTATION
HYPERABDUCTION
CONDITION PAINFUL MINIMAL PAINFUL
(OVERLOOKED)
(LIGHT BULB SIGN
ON X RAY)
SALUTE POSTURE
EXAMPLE THROWING A BALL ASSOCIATED WITH
ELECTRIC SHOCK
OR SEIZURE
DISORDER

PATHO ANTOMY
 Labral lesion
 Bankart
 Reverse-bankart
 SLAP
 Capsular Injury
 Intra-substance tear
 HAGL (humeral avulsion of glenohumeral ligament)
 Capsular laxity
 Bone loss
 Humeral head – Hill Sach’s
 Glenoid

BANKART LESION
 Traumatic detachment of the glenoid labrum has been
called the Bankart lesion.
 This disruption is between the antero-inferior labrum,
and the glenoid.
 Mechanism
 The humeral head is forced anteriorly out of the
glenoid cavity and tears not only the
fibrocartilaginous labrum from almost the entire
anterior half of the rim of the glenoid cavity but
also the capsule and periosteum from the
anterior surface of the neck of the scapula.

 The IGHLC detaches with a small piece of
avulsed glenoid, the lesion is called a bony
Bankart.
 Posterior labral pathology /disruption.
 Reverse Bankart-detached
posterior labral flap
 Kim lesion- marginal crack
without labral detachment

HILL SACH’S LESION
 A compression fracture of the posterosupero-
lateral humeral head, is known as a Hill–Sachs
lesion.
 It is a sequela of an anterior dislocation.
 The lesion is created with the arm in abduction
and external rotation with the posterior humeral
head crushed on the anterior glenoid rim

 Hill Sachs lesion are present
 80% of anterior dislocations,
 25% of anterior subluxations, and
 100% of cases of recurrent anterior instability.
 Engaging Hill–Sachs lesions- Defects which are parallel to the long
the glenoid rim in positions of function (abduction and external
and therefore “engage” or contribute to glenohumeral instability.
 Nonengaging lesions -are not parallel to the rim and therefore do not
effect stability in positions of function.

 “Reverse” Hill– Sachs on the anterior medial humeral head defect
is an important predictor of posterior recurrent instability.
(TROUGH SIGN)
 These articular humeral lesions rarely
to instability, as they are usually small;
when the lesion includes more than 20% of
articular surface and associated with
it may be an important indication for surgery

History
 Amount of initial trauma (high or low energy)
 Recurrence with minimal trauma in the mid range of motion –a/w with
bony lesion
 Position in which the dislocation has occurred
 If dislocation that occur during sleep or with the arm in an overhead
position- a/w significant glenoid defect.
 Ease with which shoulder is relocated is determined
 Associated nerve injury
 Physical limitations caused by this instability

 Be careful for subluxation – commonly overlooked
 Patient may complain of dead arm as a result of the axillary nerve stretching.
 Posterior shoulder instability may present as posterior pain or fatigue with
repeated activity(like in swimming, blocking in basketball, rowing)

Physical examination
 Begins with asking the patient which arm position creates
instability,direction of subluxation
 Look for atrophy,asymmetry.
 Tenderness- at anterior or posterior joint capsule,rotator cuff ,AC joint
 Active and passive ROM
 Power of muscles
 Winging of scapula

STABILITY OF SHOULDER JOINT
SHIFT AND LOAD TEST
PATIENT SITTING SUPINE WITH ARM SLIGHTLY ABDUCTED
AND PLACING ONE HAND ALONG SCAPULA TO STABILIZE
IT
GRASP HUMERAL HEAD WITH OTHER HAND AND
APPLYING A SLIGHT COMPRESSION FORCE
QUANTIFY THE AMOUNT OF ANTERIOR AND POSTERIOR
TRANSLATION OF HUMERAL HEAD IN GLENOID
EASY SUBLUXATION INDICATES LOSS OF CONCAVITY OF
GLENOID

SULCUS SIGN
It is positive when there is increased
inferior translation of the humeral
head relative to the glenoid, with
traction applied downward in
patients with inferior and multi-
directional instability.
The sulcus should be measured at
both neutral and 45 deg of
abduction.
Subluxation at 0 deg of abduction is
more indicative of laxity at the
rotator interval, and subluxation at
45 deg indicates laxity of inferior
GHL.

 Anterior Drawer test: Quantifies the amount of anterior
translation.
 Patient lying supine, examiner stands on the ipsilateral side. The patient’s
is positioned in the examiner’s axilla.
 Scapula is stabilized by one hand, the other hand grasps the proximal
shaft and exerts an anterior force.
 The amount of translation is quantified.

Posterior Drawer Test: Quantifies posterior
translation;
 Patient in supine position. For left shoulder, the patient’s left wrist and forearm
is held with elbow flexed to 120º.
 With the shoulder in 80-120º abduction, and 60-80º of forward flexion and
internal rotation, a posterior force is applied on the arm.
 The amount of posterior translation is assessed by the hand, stabilizing the
scapula.

 In performing these tests for anterior and posterior instability, the amount
of instability is graded from 0 to 3.
Grade 1: Humeral head slips up
to the rim of glenoid
Grade 2: Head slips over the
labrum, but spontaneously
relocates
Grade 3: Indicates dislocation.

Gagey hyperabduction test:
 Measure of laxity of the inferior glenohumeral ligament
complex.
 Patient sitting, and the examiner standing behind him, with
one hand stabilizing the scapula and the other hand
passively abducting the affected shoulder.
 A side to side difference of more than 20 deg is suggestive
of inferior capsular laxity

Apprehension test
 Patient in supine or upright position
 Anterior apprehension test: Affected shoulder
is passively moved to abduction and
maximum external rotation and a gentle
anterior force is placed on the posterior
humeral head.
 Test is positive when the patient becomes
apprehensive and experiences pain.
 Posterior apprehension test: The affected
shoulder is adducted and internally rotated.

DIAGNOSIS
Radiographs
CT Scan
MRI
Arthroscopy

X-RAY VIEWS
AP view
Axillary view
Scapular Y-view
Apical oblique view
AP in ER/IR views
Strykar notch view
West point view

 IT
 IT HELPS IN DETECTING HILL SACH’S LESION

WEST POINT VIEW FOR BANKART LESION

Scapular Y view
 Evaluate relationship of humeral head with
glenoid
 Humeral head should be located at
bifurcation of the Y shape formed by
scapula

CT SCAN
 Useful for assessing bony lesions such as Hill-Sachs
lesions, glenoid rim fracture’s, glenoid version, etc.
 CT scans with three-dimensional reconstructions are
the gold standard as MRI may underestimate the
degree of bone loss
 Indications:
Blunting of the glenoid cortical
outline or an obvious bone
defect on plain radiographs.
Evaluating recurrences that
occur with trivial trauma, low-
angle instability, and failed
surgical procedures

MRI
Gold standard for evaluating capsulo-
labral structures, especially Bankart lesion.
Addition of contrast improves ability of
MRI to show Rotater cuff pathology,
humeral avulsion of inferior glenohumeral
ligament, and capsular tears.

TREATMENT
 procedure for recurrent instability should include the following factors :
(1) low recurrence rate
(2) low complication rate
(3) low reoperation rate
(4) does no harm (arthritis)
(5) maintains motion,
(6) is applicable in most cases,
(7) allows observation of the joint,
(8) corrects the pathologic condition
(9) is not too difficult.

TREATMENT
Operative procedures can be done both – open, or arthroscopically, with
comparable results.
Open procedures include:
 Jobe capsulolabral reconstruction, or
 Neer capsular shift
Arthroscopic procedures
 Arthroscopic Bankart repair
 Capsular plication procedure.
For glenoid bony defects that cannot be repaired
 Bristow-Latarjet procedure
 Iliac Crest Autograft or Allograft Glenoid Reconstruction
 Webers osteotomy.(subcapital rotational osteotomy of proximal
humerus).

Case
NAME : SHIV KUMAR AGE 28 YEAR MALE
PRESENTED TO OPD WITH COMPLAIN OF :
 PAIN AND INSTABILITY IN RIGHT SHOULDER
 HISTORY OF RECURRENT DISLOCATION OF RIGHT
SHOULDER FROM LAST 2 YEARS
K/C/O SEIZURE DISORDER WITH LAST ATTACK 10 MONTHS
BACK
DIAGNOSED AS RECURRENT SHOULDER DISLOCATION RIGHT SIDE

ON EXAMINATION
RIGHT LEFT
DUGAS TEST - -
GAGEY HEPERABDUCTION
TEST
- -
SHIFT AND LOAD TEST + -
SULCUS SIGN - -
APPREHENSION TEST - -
GERBER LIFT OFF TEST
(SUBSCAPULARIS)
- -
DROP ARM TEST
(SUPRASPINATOUS )
+ -
JOBE EMPTY CAN TEST + -

BRISTOW-LATARJET PROCEDURE
 Indication – when bony deficiency is more
then 20 percent on glenoid
 Transfer of coracoid bone with attached
conjoined tendon provides sling effect
 Technique-coracoid bone transfer to
anterior inferior glenoid bone defect .

 The Latarjet procedure reconstructs the glenoid depth
and width with the bone block and creates a dynamic
reinforcement of the inferior capsule through the
coracobrachialis muscle, particularly while the arm is
abducted and externally rotated.
 In the Bristow procedure, only the tip of the coracoid
process and attached coracobrachialis is transferred to
the anterior glenoid

TREATMENT:LATERJET SURGERY
 patient secured in a beach-chair position and after
induction of general endotracheal anesthesia, place a
small pillow behind the scapula to position the glenoid
surface perpendicular to the operative table.
 Part scrubbed painted and drapped
 4 to 7-cm skin incision beginning under the tip of the
coracoid process is made.

 Delto-pectoral plane is made and cephalic vein
is retracted laterally , a self-retaining retractor
into the deltopectoral interval and a Hohmann
retractor on the top of the coracoid process.
 Position the patient’s arm in 90 degrees of
abduction and external rotation, and section
the coracoacromial ligament 1 cm from the
coracoid.
 release the pectoralis minor insertion from the
coracoid, osteotome or small angulated saw to
osteotomize the coracoid process from medial
to lateral at the junction of the horizontal-
vertical parts

 Grasp the bone graft ﬁrmly with forceps and carefully
release it from its deep attachments,avoiding potential
damage to the musculocutaneous nerve.
 With a 3.2-mm drill, drill two parallel holes in the deep
surface of the bone graft. Measure the thickness of the
bone graft with a caliper and place the graft under the
pectoralis major for subsequent use
 Upper limb in full external rotation, identify the inferior
and superior margins of the subscapularis tendon. Use
electrocautery and then Mayo scissors to divide the
muscle at the superior two-thirds or inferior one-third
junction in line with its ﬁbers, carefully obtaining
hemostasis at each step.

 exposing the subscapular fossa
 upper limb in neutral rotation to provide full exposure of
the capsule, and make a 1.5-cm vertical capsulotomy at the
level of the anteroinferior margin of the glenoid.
 arm into full internal rotation to allow insertion of a
humeral head retractor, which rests on the posterior
margin of the glenoid.
 Retract the superior two thirds of the subscapularis
superiorly with a Steinmann pin impacted at the superior
part of the scapular neck; retract the inferior part inferiorly
with a Hohmann retractor pushed under the neck of the
scapula between the capsule and the subscapularis

 expose the anteroinferior margin of the glenoid and
decorticate it with a curet or osteotome
 Insert the bone block through the soft tissues and
position it ﬂush to the anteroinferior margin of the
glenoid. Check the position of the bone block with the
arm in internal rotation
 Insert a 3.2-mm drill through the inferior hole in the
bone graft and into the glenoid neck in an
anteroposterior and superior direction. Check the
orientation of the articular surface and direct the drill
parallel to this plane.
 Place cancellous screw into the posterior cortex to
secure the bone block to the glenoid. Tighten this
screw loosely to allow easy rotation and proper
positioning of the superior part of the bone block

 When positioning is correct, insert a second
cancellous screw through the superior hole in the
bone block and tighten both screws firmly .
 Arm in external rotation, repair the remnant of the
coracoacromial ligament to the lateral capsular flap .
 Move the arm through all ranges of motion to
evaluate mobility. close the superficial soft-tissue
layers.

POST OP REHABILATION
 immobilization in a sling or shoulder immobilizer for 2 weeks
 Forward ﬂexion is begun thereafter, and external rotation is begun at 6
weeks.
 Strengthening exercises are started at 8 weeks after surgery.

 Stabilization of the glenohumeral joint occurs by three
mechanisms with the Latarjet procedure:
 A bony effect by correcting the anterior
glenoid deficiency.
 Muscular (“sling”) effect created by
maintaining the inferior third of the
subscapularis in an inferior position by the
conjoined tendon .
 Capsular effect by the capsular repair.

Recurrent shoulder dislocation and management

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